The invention provides an energy storage apparatus comprising: a sensible heat storage body having a heat exchanger channel and a heating element channel adapted to receive a removable heating element; and a heat exchanger having an inlet and an outlet, wherein at least a portion of the heat exchanger is disposed along the channel. Also provided are methods or reversibly storing and/or extracting energy, a heating element and an energy storage array comprising a plurality of energy storage apparatus as described herein.

The heat sink with condensing fins and phase change material is formed from a thermally conductive housing, an internal chamber, and a body of liquid phase change material. The thermally conductive housing has a first wall and an opposed second wall and forms an internal chamber. The first wall of the thermally conductive housing is adapted to be in direct contact with one or more heat sources. The body of liquid phase change material is disposed within the internal chamber. The second wall of the thermally conductive housing is adapted to form a plurality of condensing fins. The plurality of condensing fins may contain at least one high thermal conductivity rod. In some embodiments, a high thermal conductivity medium, such as gallium, is disposed within the internal chamber in direct contact with the first wall of the thermally conductive housing.

A semiconductor device package structure is provided. The semiconductor device package structure includes a substrate having a cavity, and phase change material within the cavity. In an example, the phase change material has a phase change temperature lower than 120 degree centigrade. A die may be coupled to the substrate. In an example, the semiconductor device package structure includes one or more interconnect structures that are to couple the die to the phase change material within the cavity.

A heat exchanger has (i) a first passage in which a first fluid flows, (ii) a heat storage body that is thermally connected to the first passage and stores a warm heat or a cold heat, and (iii) a second passage that is thermally connected to both of the first passage and the heat storage body, the second passage in which a second fluid flows. The heat storage body changes to a first phase in a solid state when a temperature of the heat storage body is lower than or equal to a phase transition temperature, and changes to a second phase in a solid state when the temperature of the heat storage body exceeds the phase transition temperature. The heat storage body stores or dissipates heat depending on a phase transition between the first phase and the second phase.

Embodiments herein relate to systems, apparatuses, processing, and techniques related to patterning one or more sides of a thin film capacitor (TFC) sheet, where the TFC sheet has a first side and a second side opposite the first side. The first side and the second side of the TFC sheet are metal and are separated by a dielectric layer, and the patterned TFC sheet is to provide at least one of a capacitor or a routing feature on a first side of a substrate that has the first side and a second side opposite the first side.

A latent heat storage system includes at least one latent heat storage device which contains a storage medium with latent heat, at least one extraction circuit by means of which, in accordance with the intended purpose, heat can be extracted from the storage medium, and at least one regeneration circuit by means of which, in accordance with the intended purpose, heat can be supplied into the storage medium. The at least one latent heat storage device includes at least one extraction heat exchanger which is in contact with the storage medium and can be connected to the extraction circuit, and at least one regeneration arrangement within the storage medium, which can be connected to the regeneration circuit. A coupling device is provided, by which the at least one extraction heat exchanger can be at least temporarily coupled to the at least one regeneration arrangement for common heat extraction from the storage medium or for common heat supply into the storage medium. A corresponding operating method is also provided.

A regeneration device for regenerating a coolant dispersion with phase change material includes: a redispersion unit for redispersing the coolant dispersion, the redispersion unit including a restrictor; and a recooling unit that enables freezing of a phase change material by dissipating heat stored in the coolant dispersion. The recooling unit is arranged so that dissipated heat is at least partially recuperated in order to heat up the coolant dispersion to an inlet temperature.

An energy storage and retrieval system is disclosed. The system includes a heat generating layer for generating thermal energy based on input electrical energy, a thermal energy storage layer located to receive thermal energy from the heat generating layer, the thermal energy storage section layer including a thermal energy storage material to store thermal energy. The system also includes a thermal energy retrieval layer thermally connectable to the thermal energy storage material and configurable to retrieve thermal energy from the thermal energy storage layer where the heat generating layer and the thermal energy retrieval layer are separated by the thermal energy storage layer.

Devices, systems, and methods for cooling a gas is disclosed. A slurry is passed through a droplet generating device to produce droplets of the slurry. The slurry comprises a contact liquid and solids. A melting point of the solids is higher than a vaporization point of the contact liquid. A carrier gas is passed across the droplets to exchange heat between the carrier gas and the droplets. At least a portion of the heat transferred to the droplets melts the solids.

Provided is a heat storage including a container including a first container made of ceramics and a second container made of ceramics, the first container and the second container being combined, and a heat storage material housed inside the container. The first container and the second container are bonded via a bonding member. A volume occupied by pores in the first container, in a first contact region including a surface section in contact with the bonding member, is greater than a volume occupied by pores in regions other than the first contact region. A volume occupied by pores in the second container, in a second contact region including a surface section in contact with the bonding member, is greater than a volume occupied by pores in regions other than the second contact region.